Customizable transportable structures and components therefor

ABSTRACT

A wall component and other components for a building structure wherein the wall component has a spanning beam spanning the length of the wall component, one or more structural column assemblies positioned between the spanning beam and a floor plate which are structured to carry structural weights and loads received from the spanning beam. The structural column assemblies are separated by a longitudinal distance so as to define an intercolumnar region which is greater than a width of a member selected from the group consisting of a door assembly and a window assembly, and there is an exterior panel fastened between the first and second structural column assemblies that defines a generally continuous and uninterrupted planar surface over the intercolumnar region.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Application No. 62/567,579, filed Oct. 3, 2017, and claims the benefit of U.S. Provisional Application No. 62/568,491, filed Oct. 5, 2017.

BACKGROUND OF THE INVENTION Field of the Invention

This invention relates to customizable transportable structures, components therefor, and a system for constructing structures using those components, such as dwellings and other buildings for residential occupancy, commercial occupancy and/or material storage.

Description of the Related Art

In the field of residential housing, the traditional technique for building homes is referred to as “stick-built” construction, where a builder constructs housing at the intended location using in substantial part raw materials such as wooden boards, plywood panels, and steel Lally columns. The materials are assembled piece by piece over a previously prepared portion of ground, for example, a poured concrete slab or a poured concrete or cinder block foundation.

There have been a variety of efforts to depart from the conventional construction techniques used to create dwellings, as well as commercial spaces and like. One of the alternatives to stick-built construction is very generally referred to as modular housing. As opposed to stick-built construction, where the structure is built on-site, a modular house is constructed in a factory and then shipped to the site, often by means of a tractor-trailer. A drawback of modular housing is that the prospective buyer can customize the structure layout only to a relatively limited degree. That is, while certain features, for example a closet, may be added or subtracted from a room, the general shape and layout of the house cannot be changed or adapted to the customer's preference.

Additionally, modular housing often exceeds in size normally-permitted legal limits for road transport. For example, in the United States the maximum permitted dimensions for road transport are in general 102 inches in width, 13.5 feet in height and 65 to 75 feet in length. Thus, in many cases transporting a modular house from factory to site requires oversize load permits, which may impose restrictions on when transport can be undertaken and what routes can be utilized. Oversize road regulations may also require the use of an escort car and a trailing car as well. All of these requirements and restrictions inevitably increase the cost of the modular housing.

Another alternative to stick-built construction is what is commonly referred to as a mobile home or trailer home. Mobile and trailer homes, like modular housing, are constructed in a factory and then transported to the intended location. They can be configured as two or three separate pieces which are joined at the receiving location, in which case they are referred to in the United States as a double-wide or a triple wide. Mobile and trailer homes often require less on-site finishing prior to occupancy than modular housing. On the other hand, such homes generally are almost always single story, tend to have a limited floor plan essentially dictated by transport requirements, and often cannot be customized by the buyer to any substantial degree. Like modular houses, mobile and trailer homes often exceed oversize road regulations with the attendant drawbacks described above.

A still further alternative approach to stick-built construction is to utilize wall panels (not entire houses or rooms) which are fabricated in a factory and transported to a building site for assembly into a structure and finishing. In particular, such wall boards are referred to as structural insulated panels, or SIPs for short. A SIPs panel typically is a foam core panel faced on each side with a structural board. Using SIPs in construction is often regarded as of limited benefit relative to stick-built construction, because the finishing of the house, as opposed to the framing, is generally the most expensive part of construction. In addition, SIPs are used in lieu of load-bearing vertical posts and studs, and thus bear the weight of the structure throughout their length. As a result, when apertures are cut in or positioned with SIPs where windows and doors are to be placed, the builder must insert a lintel or header across the top of each aperture to distribute vertical loads imposed from above each window and door to the load-bearing sides. This too increases the costs of using SIPs.

There are also temporary offices, or site trailers, which are similar in dimension to a trailer house. Temporary offices are typically rendered in steel, and are simply sheltered locations containing storage, office and meeting areas. They are not suitable for permanent residency or occupancy.

SUMMARY OF THE INVENTION

The present invention is a set of wall, floor and ceiling components that can be fabricated in a factory and delivered to a construction site, where they can be assembled into structures suitable for human or material occupancy, such as housing, offices, retail space, and warehouse use. The components described herein can be easily shipped from a factory to construction site. Moreover, the wall components are structured to support all designed-for vertical loads in their as-delivered state, yet can be customized on-site with doors and windows in an open-ended variety of styles, notwithstanding their factory-built nature. Additionally, the finished structures made in accordance with the inventions disclosed herein can be assembled in a multitude of configurations. Thus these inventions advantageously accord the user both the advantages of individualized customized construction and the efficiency and economy of factory fabrication.

In one aspect, the present invention is directed to a transportable wall component for a building structure having a ceiling and a member selected from the group consisting of a door assembly and a window assembly, where the wall component comprises a floor plate, a spanning beam and first and second structural column assemblies, wherein the floor plate spans the horizontal length of the wall component, the spanning beam is positioned above the floor plate and spans the horizontal length of the wall component, and the spanning beam is structured to carry structural weights and loads received from the ceiling of the building and additional floors, if any.

The wall component additionally features a first structural column assembly and a second structural column assembly, each of which are positioned between the spanning beam and the floor plate and structured to carry structural weights and loads received from the spanning beam. Further, the first and second structural column assemblies are inset from the vertical edges and separated by a longitudinal distance to define an intercolumnar region whose width is greater than the width of the member selected from the group consisting of a door assembly and a window assembly. An exterior panel fastened between the first and second structural column assemblies defines an uninterrupted planar and continuous surface over the intercolumnar region.

In another aspect, the present invention is directed to a method of constructing a building structure, wherein a shipping module is received which is comprised of a floor component, a wall component, and a ceiling component. The wall component received in this shipping module comprises a floor plate that defines the lower longitudinal edge of the wall component and which spans the horizontal length of the wall component, and a spanning beam that defines the upper longitudinal edge of the wall component. The spanning beam is positioned above the floor plate and spans the horizontal length of the wall component, and is structured to carry structural weights and loads received from the ceiling of the building and additional floors, if any.

The wall component received in this shipping module further comprises a first structural column assembly and a second structural column assembly, which are positioned between the spanning beam and the floor plate and structured to carry structural weights and loads received from the spanning beam. The first and second structural column assemblies are inset from the vertical edges and separated by a longitudinal distance to define an intercolumnar region whose width is greater than a member selected from the group consisting of a door assembly and a window assembly, and there is an exterior panel fastened between the first and second structural column assemblies to define an uninterrupted planar and continuous surface over the intercolumnar region. Means are additionally provided for rigidifying the wall component for transport.

In another aspect of the invention, the floor component is positioned over a prepared surface, the wall component is positioned over the floor component and secured to the floor component, and the ceiling component is positioned over the wall component and secured to it. Further, an aperture, defined by an edge region of the exterior panel, is opened in the intercolumnar region of the wall component, where the aperture is dimensioned to accept the member selected from the group consisting of a door assembly and a window assembly, and the member is positioned in the aperture and secured proximate to the edge region of the exterior panel.

These and other aspects of the present invention are described in the drawings annexed hereto, and in the description of the preferred embodiments and claims set forth below.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a perspective view of a finished structure prepared in accordance with the present invention.

FIG. 1B is a top view of a finished structure that includes an orthogonal grid.

FIG. 1C is a shipping module from which is formed the finished structure shown in FIG. 1A.

FIG. 1D is a side view of a shipping module prepared in accordance with the present invention.

FIG. 2A is an overall perspective view of a wall component in accordance with the present invention, with interior and exterior paneling omitted.

FIG. 2B is a cutaway perspective view of a wall component in accordance with the present invention.

FIG. 2C is a perspective view depicting in greater detail the spanning beam of the present invention.

FIG. 3A is an overall cutaway perspective view of a floor component in accordance with the present invention.

FIG. 3B is a sectional perspective view depicting the interior of a floor component and an adjacent wall component in accordance with the present invention, with sheathing and flooring omitted.

FIG. 4A is an overall perspective view of a ceiling component in accordance with the present invention.

FIG. 4B is a sectional perspective view depicting the interior of a ceiling component in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The inventions described herein are further developments of the systems described in U.S. Pat. Nos. 8,474,194 and 8,733,029, the contents of each of which are incorporated herein by reference, as if fully set forth herein.

As shown in the figures and described herein, the basic components comprising the present invention are a wall component 200, a floor component 300, and a ceiling component 400. A number of these components can be fabricated and dimensioned as described herein and positioned together to form a shipping module 100. The components are dimensioned so that the shipping module 100 is within U.S. federal highway dimensional restrictions. As a result, shipping module 100 can be transported over a limited access highway more easily, and with appropriate trailering equipment, transported without the need for oversize permits. Thus, the basic components can be manufactured in a factory, positioned together to form the shipping module, and the modules can be transported to the desired site for the structure, where they can be readily assembled and customized, as described herein.

The materials for fabricating the components herein are as disclosed, and otherwise advantageously utilize the materials customarily used in the construction industry without the need for new materials for their fabrication.

Wall Component

FIGS. 2A and 2B depict transportable wall component 200 of the present invention. Multiple numbers of wall component 200 can be employed in the present inventions to achieve a finished structure, some of which may have the same dimensions as the other(s), and some of which may not. Typically a finished structure will utilize four wall components 200.

FIG. 2A depicts the interior face of wall component 200 and FIG. 2B depicts the exterior face. Wall component 200 is defined by floor plate 220, a spanning beam 240 and one or more structural column assemblies 260. Structural column assemblies 260 position spanning beam 240 a fixed distance above floor plate 220, and support the weight of spanning beam 240 plus all structural weights and loads (such as shock loads during transport and interior loads during use) imposed on spanning beam 240. The fixed distance defines the ceiling height of the interior.

There is also an end piece 270 fastened at each vertical edge 275 of wall component 200. These end pieces 270 are not structural elements and can be removed when finishing the structure in accordance with the design preferences of the purchaser, such as to create cantilevered upper stories in a multi-story structure that utilizes the present invention, or to accommodate corner window treatments.

The regions between adjacent structural column assemblies 260 are referred to herein as intercolumnar regions 291, and are characterized as homogeneous space not containing any columns, studs or other structural members or material, although such regions can contain insulating or other nonstructural filler material. Comparably, the regions between each vertical edge 275 of wall component 200 and the adjacent structural column assembly 260 are referred to herein as extracolumnar regions 292, and are characterized as homogeneous space not containing any columns, studs or other structural members or material, although such regions can contain insulating or other barrier material.

The horizontal length of wall component 200 can vary in accordance with design considerations. Floor plate 220 spans the full horizontal length of wall component 200, and in this preferred embodiment is a continuous member, although there are plural notches 222 in floor plate 200 to receive lower column gussets 224, shown in FIG. 2B, the purpose of which will be described below.

Spanning beam 240, like floor plate 220, spans the full horizontal length of wall component 200. Referring to FIG. 2C, spanning beam 240 comprises two truss structures 242, spaced apart by a plurality of lateral spacers 243 and a beam cap 244, to form a number of connected box structures 245. Each box structure 245 has an interior void 246 through which passes a utility line 247. Utility line 247 is schematically illustrated as a single line, but can comprise multiple lines. Thus utility line 247 can be one or more of an electrical power line, a line for HVAC control, a line for security system control, a line for local area network computer and peripheral device communication, etc.

The spacers 243 each have an aperture through which utility line 247 passes between box structures 245. The two truss structures 242 of spanning beam 240 are sufficiently strong in design to bear without yielding or unduly flexing all structural weights and loads above it (e.g., upper floor(s), ceiling, etc.), and to transfer those weights and loads to structural column assemblies 260.

The exterior view of FIG. 2B shows two structural column assemblies 260. Each assembly 260 comprises a pair of columns, each of which is denoted structural column 261. The two structural columns 261 of a structural column assembly 260 are spaced apart a fixed distance to define an air space 263 in each assembly 260. As shown in the interior view of FIG. 2A, the interior face of structural column assemblies 260 are covered with a column panel 264. The structural columns 261 are sufficiently strong in design to bear all structural weights and loads transferred to the structural column assemblies 260 by the associated spanning beam 240. Wood is the preferred material for structural columns 261.

The embodiment shown in FIGS. 2A and 2B is a long wall component 200, and thus as shown has been fabricated with four structural column assemblies 260. Correspondingly shorter wall components 200 can be fabricated with fewer structural column assemblies 260; for example two structural column assemblies 260, or even one, if stability considerations permit. It is preferred however that each wall component contain one or more paired sets of structural column assemblies 260; i.e., two structural column assemblies 260, four structural column assemblies 260, etc.

The lateral placement and number of structural column assemblies 260 is dictated by structural considerations that vary in accordance with the particular design. However, in the case where two or more structural column assemblies 260 are contained in wall component 200, it is preferred that the intercolumnar distance (the horizontal distance between two adjacent structural column assemblies 260) be more than the aggregate width of a door frame assembly and/or one or more window frame assemblies, to permit placing between assemblies 260 such of those features at such locations as the purchaser may freely select. Generally, the larger the intercolumnar distance, the greater will be the freedom to custom place doors, windows and other apertures in wall component 200 in accordance with the user's needs and wants.

Further, it is preferred in the present invention that the structural column assemblies 260 contained in any wall component 200 be inset from the vertical edges 275 to which end pieces 270 are fastened, in order to liberate the corner spaces for increased interior and exterior architectural design flexibility. In particular, it is preferred that the extracolumnar distance (the horizontal distance between each vertical edge 275 of wall component 200 and the first adjacent structural column assembly 260) be more than the aggregate width of a door frame assembly and/or one or more window frame assemblies, and preferably substantially more than that width. It is also preferred that the lateral placement and number of structural column assemblies 260 be in accordance with the geometrical relationships set forth in further detail below.

Each air space 263 provides room for utility lines (for example one or more of an electrical power line, a line for HVAC control, a line for security system control, a line for local area network computer and peripheral device communication, etc.) and for service lines (for example one or more of a sewer vent line, sewer line, water line, etc.). FIG. 2B shows a vertically-disposed utility line 265 in each air space 263 that is connected to the utility line 247 running through the spanning beam 240, discussed above. Each utility line 265 is partnered with one or more junction boxes 266, which are accessible through cutouts 267 (FIG. 2A) in column panels 264. Junction boxes 266 can be used for a variety of purposes; for example, electric power outlets, electrical power switches, HVAC control panels, security system controls, data ports and the like.

To reduce the potential for racking, a lower column gusset 224 (shown in FIG. 2B) secures the bottom of each structural column assembly 260 to the floor plate 220 using four through-bolts, with two spaced-apart through-bolts passing through the structural columns 261 and two spaced-apart through-bolts passing through the floor plate 260, although the specific arrangement and means of securing the gusset 224 is a matter or design choice. The bottom portion of each lower column gusset 224 is received in the corresponding notch 222 in floor plate 220, as described previously.

Likewise, and also to reduce the potential for racking, an upper column gusset 244 (also shown in FIG. 2B) secures the top of each structural column assembly 260 to the spanning beam 240, with four spaced-apart through-bolts passing through the structural columns 261 and four spaced-apart through-bolts securing upper column gusset 244 to the spanning beam 240, although here too the specific arrangement and means of securing the gusset 244 is a matter or design choice.

The exterior surface of wall component 200 is faced with exterior skin or sheathing 281, as depicted for illustrative purposes partially cut away in FIGS. 1A and 2B. Exterior sheathing 281 optionally covers the full width and height of wall component 280 so as to be generally continuous uninterrupted and planar in that region with no cut-outs or openings for doors, windows or the like. Alternatively, exterior sheathing 281 can be dimensioned only to be generally continuous uninterrupted and planar in the intercolumnar region 291, leaving exposed structural column assemblies 260, which can then be faced with a different material than is used for sheathing 281, to achieve a pleasing architectural image. As another alternative, exterior sheathing 281 can be extended across structural column assemblies 260 while leaving exposed one or both of lower column gusset 224 and upper column gusset 244, which optionally can then be given a pleasing architectural treatment.

The interior surface of wall component 280 is depicted in FIG. 2B faced with interior skin or sheathing 282, which in this embodiment covers the full width and height of wall component 280. In finished form, the interior and exterior of wall component 280 are generally continuous uninterrupted and planar throughout with no cut-outs or openings for doors, windows or the like (except for cutouts 267). In one embodiment of the present invention, wall component 280 can be delivered in this state to the construction site. Sheathing 281, 282 preferably are formed of a material that can be sawn or cut with relative ease, particularly at a construction site.

In the void between sheathing 281 and sheathing 282, there is shown in FIG. 2B filling material 283, which can be thermal insulation, such as spun fiberglass, rigid insulation such as expanded or extruded polystyrene board or ISO panels (polyisocyanurate), blown insulation, sound absorbent insulation, or the like. Such filling material 283 can be omitted if the use for the resulting structure including wall component 200 will not require it, such as may be the case for a dry goods warehouse, which may be able to dispense with thermal insulation.

Notably, sheathing 281, 282, either alone or in combination with filling material 283, do not need to have significant strength in the vertical direction, such as to resist compressive loads. This is because all substantial structural weights and loads are transferred to the structural column assemblies 260. Therefore, in appropriate applications there need not be a bond of significant strength between sheathing 281, 282 and filling material 283, filling material 283 need not be rigid (i.e., can be pliable, such as spun fiberglass, or discrete, such as blown material, or omitted), and sheathing 281, 282 can be relatively thin in cross-section.

Accordingly, sheathing 281, 282 in one embodiment can be made of particle board. There is no need to use drywall (sold under the trademark Sheetrock®) either for structural purposes or for finishing. In another embodiment, interior sheathing 282 is fabricated of relatively thick paper, of a weight comparable to that used as the exterior surfaces of drywall. With this embodiment, interior sheathing 282 can be unrolled from a continuous roll of paper (the paper roll optionally having a width approximating the length of structural column assemblies 260), and then affixed to one or more of floor plate 220, spanning beam 240, structural column assemblies 260 and filling material 283 of wall component 280, to yield a seamless interior finish for wall component 280. This advantageously compares to conventional construction techniques, whether stick-built, SIPs or steel construction, wherein sheets of drywall first must be secured to wall elements, and then the seams between adjacent sheets must be given a smooth transition by applying mortar such as spackling compound followed by sanding. These expensive and laborious steps of interior wall finishing can be avoided by employing, in accordance with the teachings of this disclosure, a continuous roll of paper to fabricate interior sheathing 282.

In a further alternative embodiment, filling material 283 can be a dense spray foam that is strongly bound to sheathing 281, 282 (made preferably of ¼″ plywood), and also to floor plate 220, spanning beam 240 and to one or more structural column assemblies 260, to form a high strength laminate. The filling material 283 can be inserted into the wall component prior to or after applying one of sheathing 281 and 282 (but before applying the other of sheathing 281 and 282). Alternatively, after applying both of sheathing 281 and 282, the filling material can be sprayed into the wall component 280 through hatches, which will then be plugged and sealed.

Sheathing 281, 282 optionally can also be used to reduce the potential for racking by bonding either or both to two or more of spanning beam 240, floor plate 220 and structural column assemblies 260, either in addition to or in lieu of one or more of gussets 224 and 244.

In another embodiment of the present invention, tension members (not shown), such as steel rods, can be diagonally positioned in an “X” configuration and secured to adjacent structural column assemblies 260, subject to intended door and/or window placement. Use of such tension members can reduce the need for one or more of gussets 224, 244, and sheathing 281, 282, and thus provides for further freedom of design. All of these components—the diagonally positioned tension members, gussets 224, 244 and sheathing 281, 282—are means for rigidifying wall component 200 to improve its robustness during transport and erection of the structure at the construction site.

Wall component 200 lends itself to a high degree of customization in terms of type, size and location of doors, windows and the like. For example, once erected at the intended location for the structure, the builder can cut apertures in wall component 200 in accordance with the purchaser's design choices. Window and door assemblies of any number, size and shape can thus be placed anywhere in intercolumnar regions 291 and extracolumnar regions 292, limited only by practical dimensional considerations. Corner window treatments, including floor to ceiling windows, both fixed and openable, can be included with relative ease, since end pieces 270 are non-structural and can be removed, as discussed above. Neither the sheathing 281, 282 nor any filling material 283 in regions 291, 292 carry any vertical loads, and thus apertures can be cut in these regions without fear of compromising the structure's load-bearing ability, and without the need for adding on-site any load-distributing lintels or headers.

After apertures are cut to the appropriate size and shape, window assemblies and door assemblies can then be inserted and secured to wall component 200 with adhesive or by other suitable means. A wide variety of window and door assemblies are commercially available and suitable for use with the present invention. As a non-limiting example, a door assembly can include all components for mounting the door and rendering it operative, such as two side jambs, a head jamb and a sill, together with a door hinged to one of the side jambs. Likewise as a non-limiting example, a window assembly can include all components for mounting the window and rendering it operative, such as a sill, side jambs, head jambs, window frames and glass, sash pulleys and the like.

Floor Component

FIGS. 3A and 3B depict transportable floor component 300 of the present invention. Multiple numbers of floor component 300 can be employed in the present inventions to achieve a finished structure, each of which can have the same or different dimension than the other(s).

In floor component 300, a plurality of spaced-apart floor joists 320, each in this embodiment of truss design, are secured using hangers 321 to a floor girder structure 330 positioned on each of the opposite longitudinal edges of floor component 300. Floor joists transfer floor loads to the floor girder structures 330. Floor girder structures 330 receive the floor loads and transfer them to either a foundation structure or a spanning beam 240 underlying the edge, depending upon whether floor component 300 is the first floor of the structure, or a higher floor.

Floor paneling 350, such as plywood paneling, covers the floor joists 320. Such floor paneling is shown in FIG. 3A partly cut away to reveal the underlying structure. In addition, there is a stand-off plate 344 bordering floor component 300. Stand-off plate 344 defines a shallow recess in the interior region of floor component 300 for the installation of carpeting during manufacture, to assist in reducing binding when the floor component is positioned as needed to form a shipping module 100. Floor paneling 350 beneficially provides means for rigidifying floor component 300 to improve its robustness during transport and erection of the structure at the construction site.

A plurality of service lines run in a longitudinal direction through floor joists 320. In particular, there is shown in FIG. 3B a fresh water line 341 for fresh water supply. For simplicity, only one line 341 is depicted, although two lines can be provided (one for heated water, one for unheated water) in accordance with requirements. There is also shown in FIG. 3B a wastewater line 342 for receipt and transfer of grey water and/or sewage to municipal systems or other receiving systems. Optionally, there is shown in FIG. 3B utility lines 343 (for example one or more of an electrical power line, a line for HVAC control, a line for security system control, a line for local area network computer and peripheral device communication, etc.) one positioned above fresh water line 341 and waste water line 342. There can also be included in floor component 300 piping for radiant heating (not shown), in accordance with preferences.

Ceiling Component

FIGS. 4A and 4B depict transportable ceiling component 400 of the present invention. Multiple numbers of ceiling component 400 can be employed in the present inventions to achieve a finished structure, each of which can have the same or different dimension than the other(s).

Ceiling component 400 includes a plurality of spaced-apart ceiling joists 420, each in this embodiment of truss design, which are secured using hangers 421 to a ceiling girder structure 430 positioned on each of the opposite longitudinal edges of ceiling component 400. Ceiling joists 420 transfer the weight of the ceiling (plus other weights and loads as imposed from above) to the ceiling girder structures 430, where the loads are received and borne by the spanning beam 240 positioned below them, and transferred in turn to structural column assemblies 260. The underside of ceiling component 400 is surfaced with ceiling paneling 450 (not visible in the figures), which optionally can be used to surface the topside surface of ceiling component 400 as well. Ceiling paneling 450 beneficially provides means for rigidifying ceiling component 400 to improve its robustness during transport and erection of the structure at the construction site.

In this embodiment, and as shown in FIG. 4A, a utility line 443 (for example one or more of an electrical power line, a line for HVAC control, a line for security system control, a line for local area network computer and peripheral device communication, etc.) is run through ceiling joists 420 generally in a longitudinal direction. Line 443 enters ceiling component 400 through a first of the ceiling girders 430 at a first longitudinal distance from a distal edge of ceiling component 400 to form a U-shaped loop that exits a second of the ceiling girders 430 of ceiling component 400 at approximately the first longitudinal distance from the distal edge. In the case where multiple ceiling components 400 are use, this utility line configuration permits connecting the utility lines 443 in series to create one continuous utility line traversing the ceiling in a sinuous fashion.

In addition to utility line 443, ceiling component 400 further includes an HVAC duct 444 positioned in a transverse orientation through ceiling joists 420. Louvres and apertures are connected to duct 444 through ceiling paneling 450 at appropriate locations to supply ventilation, cooled air, and/or heated air to the spaces below ceiling component 400. In addition, a water line can be positioned through ceiling joists 420 to provide fire retardant/extinguishing fluid (such as water) to overhead sprinklers or like delivery mechanisms positioned at appropriate locations.

Component Design Relationships

For ease of transport and maximum design flexibility, it is preferred that there be a specific dimensional relationship among elements 200, 300 and 400, as explained below.

FIG. 1A shows a finished structure 150 formed using elements 200, 300 and 400, and FIG. 1B shows a top schematic view of the finished structure 150, which includes a geometrical orthogonal grid for clarity of explaining the dimensional relationships among components 200, 300 and 400. The basic length used for dimensioning is indicated as “E” in FIG. 1B; the orthogonal grid overlaid in FIG. 1B is 24E long and 12 E wide, and illustrates the relative dimensions of the components.

More particularly, FIG. 1B depicts two long wall components 200 a that are approximately 24E long, and two short wall components 200 b that are approximately 12E long. The two long wall components 200 a each contains four structural column assemblies 260 (two pairs), and the two short wall components 200 b each contains two structural column assemblies 260 (one pair). The structural column assemblies 260 preferably are approximately E in width, as shown in the figure.

The two structural column assemblies 260 in short wall component 200 b are symmetrically disposed about the mid-point of wall component 200 b and separated each from the other by a distance of approximately 2E. Each long wall component 200 a in terms of geometrical relationship is a replication of two short wall components 200 b placed edge 275 to edge 275.

Finished structure 150 includes three ceiling components 400, denominated 400 a, 400 b and 400 c in FIGS. 1B, 1C and 1D. Each ceiling component of 400 a, 400 b and 400 c is 24E long and 4E wide.

Finished structure 150 further includes two floor components 300 denominated, 300 a and 300 b and shown in FIGS. 1C and 1D. Each of floor components 300 a and 300 b is 24E long; whereas floor component 300 a is approximately 4E wide and floor component 300 b is approximately 8E wide.

Components 200, 300 and 400 sized according to the dimensional relationships disclosed above can be positioned as shown in FIGS. 1C and 1D to form a shipping module 100. In the embodiment disclosed in those figures, short wall components 200 b are each hinged to fold about a vertical axis, denominated 200 bp in FIG. 1B, so as to assist in producing a compact shipping module. Thus as shown in FIGS. 1C and 1D, fixed portion 200 b-1 of each short wall component is fixed in position, while the pivoting portion 200 b-2 is folded inward. Referring again to FIG. 1B, fixed portion 200 b-2 is shown both in its unfolded orientation as 200 b-2 u, and in its folded inward orientation as 200 b-2 f.

Shipping module 100 includes a fixed space portion 102 defined by ceiling component 400 a, floor component 300 a, a long wall component 200 a and fixed portions 200 b-1 of short wall components 200 b. The remaining portion of short wall components 200 b, pivoting portions 200 b-2, are folded vertically inward and positioned against fixed space portion 102. As explained above, the finished structure 150 is formed from three ceiling components 400 a, 400 b and 400 c; thus FIGS. 1C and 1D depict two additional ceiling components 400 b and 400 c stacked on top of the ceiling component 400 a that in part defines fixed space portion 102. In turn, a second long wall component 200 a is vertically positioned against outside pivoting portions 200 b-2, and floor component 300 b is vertically positioned against the second long wall component 200 a.

Sizing components 200, 300 and 400 according to the dimensional relationships disclosed herein yields a compact shipping module 100, as can be seen from the figures. Further, when dimension “E” (see FIG. 1B) is 19.5 inches, the overall dimensions of shipping module 100 are approximately the same or less than a typical shipping container. Thus shipping module 100, when dimensioned according to the relationships disclosed herein using an “E” dimension of 19.5 inches, and when its components are stacked and positioned as shown in FIGS. 1C and 1D, has an overall length of approximately 39 feet, an overall width of approximately 8.5 feet and an overall height of 12.67 feet.

In addition, sizing components 200, 300 and 400 according to the dimensional relationships disclosed herein provides great flexibility in positioning together any number of finished structures 150 in the course of erection at the desired site, to yield a multitude of different structural configurations. For example, two finished structures 150 can be erected so that a wall component 200 of one structure is placed in contact with a wall component 200 of the other structure, with any of intercolumnar regions 291 and extracolumnar regions 292 of the two wall components 200 being juxtaposed. The builder can then cut apertures in those juxtaposed regions to connect the two structures in accordance with the purchaser's design choices. The location, size and shape of the connection is infinitely variable, in accordance with the purchaser's design choices, and is limited only by practical dimensional considerations such as the width of the juxtaposed intercolumnar/extracolumnar regions and the height of wall component 200.

Shipping Module Assembly

It is preferred that the fixed space portion 102 be in a relatively finished state prior to positioning together all other of the components 200, 300 and 400 as described above. That is, the fixed space portion 102 is preferably fitted during manufacture with all mechanical and other functionality that the structure 150 will require, such as kitchens, bathrooms, laundry rooms, HVAC closets, fireplaces, clothing closets, storage areas, corridors, etc. A temporary member 103 (shown in FIGS. 1C and 1D) provides support during shipping and is removed after delivery.

Preferably after fixed space portion 102 is finished to the desired state, the remaining components are stacked and positioned against fixed space portion 102 as described above. The components so stacked and positioned preferably are pivotally attached to the fixed space portion 102 at the locations 105 shown in FIG. 1D, to permit them to pivot about a horizontal axis during construction and to permit the user, in effect, to erect finished structure 150 simply by “unfolding” the positioned components. The stacked and positioned components can be pivotally attached at locations 105 by means of mechanical or flexible hinge mechanisms, surface mounted or recessed, and including, but not limited to, metal, plastic, leather, ferrous or non-ferrous material.

Each component 200, 300 and 400 can be sheathed in protective film 177 during fabrication and prior to forming the shipping module 100, an example of which is schematically illustrated in cutaway view in FIG. 1C as sheathing ceiling component 400 c. Alternatively or in addition, the entire shipping module 100 can be sheathed in a protective film. These protective films accordingly constitute a means for protecting the shipping module 100 and components 200, 300 and 400 during shipping. In addition to the protection they give to the module and its components, such protective films have the added benefit of increasing the resistance of the components to such flexural and torsional stresses as may occur during transport of the components. These protective films constitute further means for rigidifying wall component 200 to improve its robustness during transport and erection of the structure at the construction site. It is preferred that such protective films remain in place until after the shipping module 100 is at the construction site. It is particularly preferred that the protective films sheathing each component 200, 300 and 400 remain in place until after the completion of erection, site work and all trade egress.

The shipping module is shipped to the building site by appropriate means. One such means is disclosed in U.S. Provisional Application No. 62/568,491, filed Oct. 5, 2017, the contents of which are incorporated by reference as if fully set forth herein. After the fixed space portion 102 is positioned over its desired location, such as on a poured concrete slab or a poured concrete or cinder block foundation, the components 200, 300 and 400 are “unfolded” in accordance with the sequence dictated by their interpositioned relationship in shipping module 100, the portions 200 b-1 and 200 b-2 of the short wall components 200 b are bolted together (particularly at the spanning beam 240) to yield a rigid wall, and the other components are secured together to form finished structure 150, shown in FIG. 1A. The hinge mechanisms at locations 105 can then be removed.

Following assembly, in the case where lines 247 and 443 are electrical power lines, then the electrical power line 247 in each spanning beam 240 is connected to the electrical power line 443 in a ceiling component 400, the electrical power lines 443 in the three ceiling components 400 are connected in series, and those lines in turn are connected to the electric utility's service drop, thus energizing the structure's electrical service.

Prior to, during or following this assembly, as desired, apertures for one or more doors and windows are cut at desired locations in the intercolumnar and/or extracolumnar regions 291, 292 of wall components 200, and appropriate door and window assemblies are positioned and fastened in the apertures. Additional municipal hook-ups are made to the water line 341, the sewer line 342 to complete the structure, as relevant here.

As discussed above, any number of finished structures 150 can be positioned together at the desired site, to yield a multitude of different structural configurations. In addition, finished structures 150 can be stacked, one on top of the other, to yield multi-story structures. Interior staircases for such multi-story structures can be provided during manufacture in fixed space portion 102, together with insertion of an appropriate access aperture in ceiling 400 a, or can be added after erection. Likewise, a pitched roof and other architectural additions can be delivered separately from shipping module 100 or fabricated on-site, and positioned onto ceiling components 400 of finished structure 150.

The foregoing detailed description is for illustration only and is not to be deemed as limiting the invention, which is defined in the appended claims. 

What is claimed is:
 1. A transportable wall component for a building structure having a ceiling and a member selected from the group consisting of a door assembly and a window assembly, the transportable wall component having a horizontal length and two vertical edges, and the member having a width, the transportable wall component comprising: a floor plate defining a lower longitudinal edge of the transportable wall component and spanning the horizontal length of the transportable wall component; a spanning beam defining an upper longitudinal edge of the transportable wall component, said spanning beam positioned above the floor plate and spanning the horizontal length of the transportable wall component; the floor plate, spanning beam and two vertical edges defining a boundary of the transportable wall component and an interior region inside the boundary of the transportable wall component; the spanning beam adapted to carry structural weights and loads received from the ceiling of the building structure and any additional floors; a wall structural system that transfers substantially all vertical loads imposed on the spanning beam to the floor plate consisting essentially of two to four structural column assemblies, each of the two to four structural column assemblies positioned between the spanning beam and the floor plate, the two to four structural column assemblies structured to carry substantially all structural weights and loads imposed on the spanning beam; the two to four structural column assemblies inset from the vertical edges and positioned inside the boundary within the interior region of the transportable wall component, a first structural column assembly and a second structural column assembly of the two to four structural column assemblies being separated from each other by a longitudinal distance to define an intercolumnar region having a width within the interior region, the width of the intercolumnar region being greater than the width of the member; an exterior panel positioned between the first and second structural column assemblies and bonded to two or more of the floor plate, the spanning beam, the first structural column assembly and the second structural column assembly to define a generally continuous and uninterrupted planar surface over an exterior face of the intercolumnar region; the first structural column assembly comprising (a) two spaced-apart columns to define an air space there between, (b) a column panel spanning the air space between the two spaced-apart columns, (c) a junction box positioned in a cutout of the column panel, and (d) a utility line in the air space accessible through the junction box; and a removable protective film enclosing the exterior of the transportable wall component for protecting the transportable wall component during transport.
 2. The transportable wall component of claim 1, further comprising an interior surface positioned between the first and second structural column assemblies in an opposing relationship to the exterior panel and bonded to two or more of the floor plate, the spanning beam, the first structural column assembly and the second structural column assembly to define a generally continuous and uninterrupted planar surface over an interior face of the intercolumnar region and to further define an interior volume of the interior region, the interior volume bounded by the floor plate, the spanning beam, the first structural column assembly, the second structural column assembly, the exterior panel and the interior surface.
 3. The transportable wall component of claim 2, wherein the interior volume is substantially filled with filling material.
 4. The transportable wall component of claim 3, wherein the interior surface is paper.
 5. The transportable wall component of claim 1, further comprising a first gusset securing the first structural column assembly to either the floor plate or the spanning beam.
 6. The transportable wall component of claim 5, wherein the first gusset secures the first structural column assembly to the floor plate, and further comprising a second gusset securing the first structural column assembly to the spanning beam.
 7. The transportable wall component of claim 3, wherein the filling material comprises a rigid insulation board.
 8. The transportable wall component of claim 3, wherein the filling material comprises spun fiberglass.
 9. The transportable wall component of claim 6, wherein the two spaced-apart columns of the first structural column assembly are spaced apart by less than approximately 19.5 inches to define the air space there between. 